{
 "cells": [
  {
   "cell_type": "markdown",
   "metadata": {
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   },
   "source": [
    "# Deep Convolutional Generative Adversarial Network Example\n",
    "\n",
    "Build a deep convolutional generative adversarial network (DCGAN) to generate digit images from a noise distribution with TensorFlow.\n",
    "\n",
    "- Author: Aymeric Damien\n",
    "- Project: https://github.com/aymericdamien/TensorFlow-Examples/"
   ]
  },
  {
   "cell_type": "markdown",
   "metadata": {},
   "source": [
    "## DCGAN Overview\n",
    "\n",
    "<img src=\"https://camo.githubusercontent.com/45e147fc9dfcf6a8e5df2c9b985078258b9974e3/68747470733a2f2f63646e2d696d616765732d312e6d656469756d2e636f6d2f6d61782f313030302f312a33394e6e6e695f6e685044614c7539416e544c6f57772e706e67\" alt=\"dcgan\" style=\"width: 1000px;\"/>\n",
    "\n",
    "References:\n",
    "- [Unsupervised representation learning with deep convolutional generative adversarial networks](https://arxiv.org/pdf/1511.06434). A Radford, L Metz, S Chintala, 2016.\n",
    "- [Understanding the difficulty of training deep feedforward neural networks](http://proceedings.mlr.press/v9/glorot10a.html). X Glorot, Y Bengio. Aistats 9, 249-256\n",
    "- [Batch Normalization: Accelerating Deep Network Training by Reducing Internal Covariate Shift](https://arxiv.org/abs/1502.03167). Sergey Ioffe, Christian Szegedy. 2015.\n",
    "\n",
    "## MNIST Dataset Overview\n",
    "\n",
    "This example is using MNIST handwritten digits. The dataset contains 60,000 examples for training and 10,000 examples for testing. The digits have been size-normalized and centered in a fixed-size image (28x28 pixels) with values from 0 to 1. For simplicity, each image has been flattened and converted to a 1-D numpy array of 784 features (28*28).\n",
    "\n",
    "![MNIST Dataset](http://neuralnetworksanddeeplearning.com/images/mnist_100_digits.png)\n",
    "\n",
    "More info: http://yann.lecun.com/exdb/mnist/"
   ]
  },
  {
   "cell_type": "code",
   "execution_count": 1,
   "metadata": {
    "collapsed": true
   },
   "outputs": [],
   "source": [
    "from __future__ import division, print_function, absolute_import\n",
    "\n",
    "import matplotlib.pyplot as plt\n",
    "import numpy as np\n",
    "import tensorflow as tf"
   ]
  },
  {
   "cell_type": "code",
   "execution_count": 2,
   "metadata": {},
   "outputs": [
    {
     "name": "stdout",
     "output_type": "stream",
     "text": [
      "Extracting /tmp/data/train-images-idx3-ubyte.gz\n",
      "Extracting /tmp/data/train-labels-idx1-ubyte.gz\n",
      "Extracting /tmp/data/t10k-images-idx3-ubyte.gz\n",
      "Extracting /tmp/data/t10k-labels-idx1-ubyte.gz\n"
     ]
    }
   ],
   "source": [
    "# Import MNIST data\n",
    "from tensorflow.examples.tutorials.mnist import input_data\n",
    "mnist = input_data.read_data_sets(\"/tmp/data/\", one_hot=True)"
   ]
  },
  {
   "cell_type": "code",
   "execution_count": 3,
   "metadata": {
    "collapsed": true
   },
   "outputs": [],
   "source": [
    "# Training Params\n",
    "num_steps = 10000\n",
    "batch_size = 128\n",
    "lr_generator = 0.002\n",
    "lr_discriminator = 0.002\n",
    "\n",
    "# Network Params\n",
    "image_dim = 784 # 28*28 pixels * 1 channel\n",
    "noise_dim = 100 # Noise data points"
   ]
  },
  {
   "cell_type": "code",
   "execution_count": 4,
   "metadata": {
    "collapsed": true
   },
   "outputs": [],
   "source": [
    "# Build Networks\n",
    "# Network Inputs\n",
    "noise_input = tf.placeholder(tf.float32, shape=[None, noise_dim])\n",
    "real_image_input = tf.placeholder(tf.float32, shape=[None, 28, 28, 1])\n",
    "# A boolean to indicate batch normalization if it is training or inference time\n",
    "is_training = tf.placeholder(tf.bool)\n",
    "\n",
    "#LeakyReLU activation\n",
    "def leakyrelu(x, alpha=0.2):\n",
    "    return 0.5 * (1 + alpha) * x + 0.5 * (1 - alpha) * abs(x)\n",
    "\n",
    "# Generator Network\n",
    "# Input: Noise, Output: Image\n",
    "# Note that batch normalization has different behavior at training and inference time,\n",
    "# we then use a placeholder to indicates the layer if we are training or not.\n",
    "def generator(x, reuse=False):\n",
    "    with tf.variable_scope('Generator', reuse=reuse):\n",
    "        # TensorFlow Layers automatically create variables and calculate their\n",
    "        # shape, based on the input.\n",
    "        x = tf.layers.dense(x, units=7 * 7 * 128)\n",
    "        x = tf.layers.batch_normalization(x, training=is_training)\n",
    "        x = tf.nn.relu(x)\n",
    "        # Reshape to a 4-D array of images: (batch, height, width, channels)\n",
    "        # New shape: (batch, 7, 7, 128)\n",
    "        x = tf.reshape(x, shape=[-1, 7, 7, 128])\n",
    "        # Deconvolution, image shape: (batch, 14, 14, 64)\n",
    "        x = tf.layers.conv2d_transpose(x, 64, 5, strides=2, padding='same')\n",
    "        x = tf.layers.batch_normalization(x, training=is_training)\n",
    "        x = tf.nn.relu(x)\n",
    "        # Deconvolution, image shape: (batch, 28, 28, 1)\n",
    "        x = tf.layers.conv2d_transpose(x, 1, 5, strides=2, padding='same')\n",
    "        # Apply tanh for better stability - clip values to [-1, 1].\n",
    "        x = tf.nn.tanh(x)\n",
    "        return x\n",
    "\n",
    "\n",
    "# Discriminator Network\n",
    "# Input: Image, Output: Prediction Real/Fake Image\n",
    "def discriminator(x, reuse=False):\n",
    "    with tf.variable_scope('Discriminator', reuse=reuse):\n",
    "        # Typical convolutional neural network to classify images.\n",
    "        x = tf.layers.conv2d(x, 64, 5, strides=2, padding='same')\n",
    "        x = tf.layers.batch_normalization(x, training=is_training)\n",
    "        x = leakyrelu(x)\n",
    "        x = tf.layers.conv2d(x, 128, 5, strides=2, padding='same')\n",
    "        x = tf.layers.batch_normalization(x, training=is_training)\n",
    "        x = leakyrelu(x)\n",
    "        # Flatten\n",
    "        x = tf.reshape(x, shape=[-1, 7*7*128])\n",
    "        x = tf.layers.dense(x, 1024)\n",
    "        x = tf.layers.batch_normalization(x, training=is_training)\n",
    "        x = leakyrelu(x)\n",
    "        # Output 2 classes: Real and Fake images\n",
    "        x = tf.layers.dense(x, 2)\n",
    "    return x\n",
    "\n",
    "# Build Generator Network\n",
    "gen_sample = generator(noise_input)\n",
    "\n",
    "# Build 2 Discriminator Networks (one from noise input, one from generated samples)\n",
    "disc_real = discriminator(real_image_input)\n",
    "disc_fake = discriminator(gen_sample, reuse=True)\n",
    "\n",
    "# Build the stacked generator/discriminator\n",
    "stacked_gan = discriminator(gen_sample, reuse=True)\n",
    "\n",
    "# Build Loss (Labels for real images: 1, for fake images: 0)\n",
    "# Discriminator Loss for real and fake samples\n",
    "disc_loss_real = tf.reduce_mean(tf.nn.sparse_softmax_cross_entropy_with_logits(\n",
    "    logits=disc_real, labels=tf.ones([batch_size], dtype=tf.int32)))\n",
    "disc_loss_fake = tf.reduce_mean(tf.nn.sparse_softmax_cross_entropy_with_logits(\n",
    "    logits=disc_fake, labels=tf.zeros([batch_size], dtype=tf.int32)))\n",
    "# Sum both loss\n",
    "disc_loss = disc_loss_real + disc_loss_fake\n",
    "# Generator Loss (The generator tries to fool the discriminator, thus labels are 1)\n",
    "gen_loss = tf.reduce_mean(tf.nn.sparse_softmax_cross_entropy_with_logits(\n",
    "    logits=stacked_gan, labels=tf.ones([batch_size], dtype=tf.int32)))\n",
    "\n",
    "# Build Optimizers\n",
    "optimizer_gen = tf.train.AdamOptimizer(learning_rate=lr_generator, beta1=0.5, beta2=0.999)\n",
    "optimizer_disc = tf.train.AdamOptimizer(learning_rate=lr_discriminator, beta1=0.5, beta2=0.999)\n",
    "\n",
    "# Training Variables for each optimizer\n",
    "# By default in TensorFlow, all variables are updated by each optimizer, so we\n",
    "# need to precise for each one of them the specific variables to update.\n",
    "# Generator Network Variables\n",
    "gen_vars = tf.get_collection(tf.GraphKeys.TRAINABLE_VARIABLES, scope='Generator')\n",
    "# Discriminator Network Variables\n",
    "disc_vars = tf.get_collection(tf.GraphKeys.TRAINABLE_VARIABLES, scope='Discriminator')\n",
    "\n",
    "# Create training operations\n",
    "# TensorFlow UPDATE_OPS collection holds all batch norm operation to update the moving mean/stddev\n",
    "gen_update_ops = tf.get_collection(tf.GraphKeys.UPDATE_OPS, scope='Generator')\n",
    "# `control_dependencies` ensure that the `gen_update_ops` will be run before the `minimize` op (backprop)\n",
    "with tf.control_dependencies(gen_update_ops):\n",
    "    train_gen = optimizer_gen.minimize(gen_loss, var_list=gen_vars)\n",
    "disc_update_ops = tf.get_collection(tf.GraphKeys.UPDATE_OPS, scope='Discriminator')\n",
    "with tf.control_dependencies(disc_update_ops):\n",
    "    train_disc = optimizer_disc.minimize(disc_loss, var_list=disc_vars)\n",
    "    \n",
    "# Initialize the variables (i.e. assign their default value)\n",
    "init = tf.global_variables_initializer()"
   ]
  },
  {
   "cell_type": "code",
   "execution_count": 5,
   "metadata": {},
   "outputs": [
    {
     "name": "stdout",
     "output_type": "stream",
     "text": [
      "Step 1: Generator Loss: 3.590350, Discriminator Loss: 1.907586\n",
      "Step 500: Generator Loss: 1.254698, Discriminator Loss: 1.005236\n",
      "Step 1000: Generator Loss: 1.730409, Discriminator Loss: 0.837684\n",
      "Step 1500: Generator Loss: 1.962198, Discriminator Loss: 0.618827\n",
      "Step 2000: Generator Loss: 2.767945, Discriminator Loss: 0.378071\n",
      "Step 2500: Generator Loss: 2.370605, Discriminator Loss: 0.561247\n",
      "Step 3000: Generator Loss: 3.427798, Discriminator Loss: 0.402951\n",
      "Step 3500: Generator Loss: 4.904454, Discriminator Loss: 0.554856\n",
      "Step 4000: Generator Loss: 4.045284, Discriminator Loss: 0.454970\n",
      "Step 4500: Generator Loss: 4.577699, Discriminator Loss: 0.687195\n",
      "Step 5000: Generator Loss: 3.476081, Discriminator Loss: 0.210492\n",
      "Step 5500: Generator Loss: 3.898139, Discriminator Loss: 0.143352\n",
      "Step 6000: Generator Loss: 4.089877, Discriminator Loss: 1.082561\n",
      "Step 6500: Generator Loss: 5.911457, Discriminator Loss: 0.154059\n",
      "Step 7000: Generator Loss: 3.594872, Discriminator Loss: 0.152970\n",
      "Step 7500: Generator Loss: 6.067883, Discriminator Loss: 0.084864\n",
      "Step 8000: Generator Loss: 6.737456, Discriminator Loss: 0.402566\n",
      "Step 8500: Generator Loss: 6.630128, Discriminator Loss: 0.034838\n",
      "Step 9000: Generator Loss: 6.480587, Discriminator Loss: 0.427419\n",
      "Step 9500: Generator Loss: 7.200409, Discriminator Loss: 0.124268\n",
      "Step 10000: Generator Loss: 5.479313, Discriminator Loss: 0.191389\n"
     ]
    }
   ],
   "source": [
    "# Start Training\n",
    "# Start a new TF session\n",
    "sess = tf.Session()\n",
    "\n",
    "# Run the initializer\n",
    "sess.run(init)\n",
    "    \n",
    "# Training\n",
    "for i in range(1, num_steps+1):\n",
    "\n",
    "    # Prepare Input Data\n",
    "    # Get the next batch of MNIST data (only images are needed, not labels)\n",
    "    batch_x, _ = mnist.train.next_batch(batch_size)\n",
    "    batch_x = np.reshape(batch_x, newshape=[-1, 28, 28, 1])\n",
    "    # Rescale to [-1, 1], the input range of the discriminator\n",
    "    batch_x = batch_x * 2. - 1.\n",
    "\n",
    "    # Discriminator Training\n",
    "    # Generate noise to feed to the generator\n",
    "    z = np.random.uniform(-1., 1., size=[batch_size, noise_dim])\n",
    "    _, dl = sess.run([train_disc, disc_loss], feed_dict={real_image_input: batch_x, noise_input: z, is_training:True})\n",
    "    \n",
    "    # Generator Training\n",
    "    # Generate noise to feed to the generator\n",
    "    z = np.random.uniform(-1., 1., size=[batch_size, noise_dim])\n",
    "    _, gl = sess.run([train_gen, gen_loss], feed_dict={noise_input: z, is_training:True})\n",
    "    \n",
    "    if i % 500 == 0 or i == 1:\n",
    "        print('Step %i: Generator Loss: %f, Discriminator Loss: %f' % (i, gl, dl))"
   ]
  },
  {
   "cell_type": "code",
   "execution_count": 6,
   "metadata": {},
   "outputs": [
    {
     "data": {
      "image/png": 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6VWlTPKyiPmRNdO/ePcySVIRH1A+fDUjxSHkrG1cRH8pSVY2WTKL8BD2WhmoF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\nNLSZp2OoG2VZU9CVwr755psDPsnpvffeS+o4K8I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      "text/plain": [
       "<matplotlib.figure.Figure at 0x7f5a71a99650>"
      ]
     },
     "metadata": {},
     "output_type": "display_data"
    }
   ],
   "source": [
    "# Testing\n",
    "# Generate images from noise, using the generator network.\n",
    "n = 6\n",
    "canvas = np.empty((28 * n, 28 * n))\n",
    "for i in range(n):\n",
    "    # Noise input.\n",
    "    z = np.random.uniform(-1., 1., size=[n, noise_dim])\n",
    "    # Generate image from noise.\n",
    "    g = sess.run(gen_sample, feed_dict={noise_input: z, is_training:False})\n",
    "    # Rescale values to the original [0, 1] (from tanh -> [-1, 1])\n",
    "    g = (g + 1.) / 2.\n",
    "    # Reverse colours for better display\n",
    "    g = -1 * (g - 1)\n",
    "    for j in range(n):\n",
    "        # Draw the generated digits\n",
    "        canvas[i * 28:(i + 1) * 28, j * 28:(j + 1) * 28] = g[j].reshape([28, 28])\n",
    "\n",
    "plt.figure(figsize=(n, n))\n",
    "plt.imshow(canvas, origin=\"upper\", cmap=\"gray\")\n",
    "plt.show()"
   ]
  }
 ],
 "metadata": {
  "kernelspec": {
   "display_name": "Python 2",
   "language": "python",
   "name": "python2"
  },
  "language_info": {
   "codemirror_mode": {
    "name": "ipython",
    "version": 2
   },
   "file_extension": ".py",
   "mimetype": "text/x-python",
   "name": "python",
   "nbconvert_exporter": "python",
   "pygments_lexer": "ipython2",
   "version": "2.7.12"
  }
 },
 "nbformat": 4,
 "nbformat_minor": 2
}
